JPH0135973Y2 - - Google Patents

Description

[Detailed Description of the Invention] Industrial Application Field The present invention relates to a variable diameter V-pulley used, for example, in a continuously variable transmission of a motorcycle, and particularly to a shock absorbing device thereof.

Future technology Conventionally, in motorcycles and other vehicles, continuously variable transmissions change the speed of the engine's rotational power and transmit it to the axle.
A fixed pulley half and a movable pulley half that can be moved in the axial direction so as to be able to move forward and backward with respect to the fixed pulley half are provided on the rotating shaft, and the weight provided on the movable pulley half is controlled by changes in the rotational speed of the rotating shaft. The movable pulley half is moved in the radial direction by increasing or decreasing centrifugal force, and the movable pulley half is adjusted forward or backward relative to the fixed pulley half, and the fixed and movable pulley halves are moved by changing the rotational speed of the rotating shaft. A centrifugal force-adjustable variable diameter V pulley that can adjust the interval between the V-shaped grooves formed between them is used. It is shown.

Problems that the invention aims to solve However, when such a variable diameter V-pulley is used for motorcycles, etc., the V-belt may slip due to engine torque fluctuations, or the V-belt may be subject to intermittent loads. Because the belt used to flap,
This affected the durability of the belt.

This torque fluctuation becomes a particular problem when transmitting a large torque at high rotational speeds, and as a result of torque fluctuation, a shocking load is applied to each part, each part must be made sturdy to withstand this load. Furthermore, noises such as a banging sound and a flapping sound of the belt were generated due to the impact.

Means and Effects for Solving the Problems In order to solve the above problems, in the present invention, both the fixed and movable pulley halves are supported on a face portion forming a conical surface and a bearing supported on a rotating shaft, respectively. It is constructed by integrating the parts with each other via an elastic buffer member.

According to the present invention, even if the torque transmitted from the rotating shaft to the face portion fluctuates, the torque fluctuation is alleviated by the elastic buffer member, and the transmitted torque is averaged.

Since the above-mentioned elastic buffer members are provided on both the fixed pulley half and the movable pulley half, an averaged torque with reduced fluctuations is transmitted to both half pulleys, thereby preventing belt slippage. There is less flapping and the durability of the belt is improved. Furthermore, since the impact force caused by torque fluctuations is reduced, the strength required for each component is also reduced, making it possible to reduce weight and cost. Furthermore, noise is also reduced.

Embodiment FIG. 1 shows an embodiment in which the variable diameter V-pulley of the present invention is implemented on the drive side of a continuously variable transmission. Rotation shaft 1 (drive rotation shaft) interlocked with an appropriate drive source (not shown)
includes a fixed pulley half 2 and a movable pulley half 3.
A driving side V-pulley _P1 is provided.
That is, a boss 5 is fitted to a small diameter portion 4 formed at the end of the rotating shaft 1, and a disk-shaped stationary pulley half 2 having a conical surface 6 is spline-coupled to the small diameter portion 4. Natsuto 7 screwed into the part
It is fixed to the rotating shaft 1 by. Further, a short cylindrical movable pulley half 3 having a conical surface 8 is fitted onto the boss 5 so as to be slidable in the axial direction.
and the conical surface 8 are opposed to each other, and a V-shaped groove 9 is formed between them.
is formed. Endless V-belt 1 inside V-shaped groove 9
0 is charged, and both end surfaces thereof are held between the conical surfaces 6 and 8.

The fixed pulley half 2 consists of a bearing part 11 spline-coupled to the small diameter part 4 of the rotating shaft 1 and supported by the rotating shaft 1, and a face part 12 forming the conical surface 6, and these parts 11, 12 are integrally connected via an elastic buffer member, that is, a damper rubber 13. Both sides of the damper rubber 13 are a support portion 11 and a face portion 12, respectively.
It is strongly joined to each surface of the bearing part 11 and buffers fluctuations in the torque transmitted from the bearing part 11 to the face part 12 by its shear elasticity.

The movable pulley half 3 having a short cylindrical shape is provided with a ramp plate 15 inside the sliding portion 14 having the conical surface 8. A plurality of inclined support surfaces 16 are formed which are inclined toward the moving part 14, while the ramp plate 15 of the sliding part 14 is
An inclined support surface 17 that is inclined radially outward toward the lamp plate 15 is formed on the back surface facing the ramp plate 15, and a weight roller 18 is housed and held between both inclined support surfaces 16 and 17. . A plurality of bifurcated slide pieces 19 are also fixed to the outer periphery of the lamp plate 15 at equal intervals in the circumferential direction, and these slide pieces 19 are attached to the sliding portion 1
A plurality of guide pieces 20 are protruded from the inner circumferential wall of the back surface of No. 4 at equal intervals in the circumferential direction. Therefore, the sliding portion 14 is connected to the guide piece 2
0 and the slide piece 19, and slides in the axial direction of the rotating shaft 1 without rotating relative to the lamp plate 15.

The lamp plate 15 is integrally connected to the lamp plate boss 22 via an elastic buffer member similar to the damper rubber 13 of the fixed pulley half 2, that is, a damper rubber 21. The lamp plate boss 22 is fixed to the rotary shaft 1 by being tightened between the stepped portion 23 of the rotary shaft 1 and the boss 5, and therefore the torque of the rotary shaft 1 is applied to the lamp plate boss 2.
2, damper rubber 21, lamp plate 15,
The torque is transmitted to the sliding portion 14 via the slide piece 19 and the guide piece 20, and these rotate as a unit. However, when the transmitted torque fluctuates, the damper rubber 21
Fluctuations in transmitted torque are buffered by the shear elasticity of That is, in the movable pulley half 3, the lamp plate boss 22 is a supporting part supported on the rotating shaft, and the sliding part 14 and lamp plate 15, which are integrated through the slide piece 19 and the guide piece 20, form a conical surface. Constitutes the face part.

Reference numeral 24 denotes a driven rotating shaft arranged parallel to the rotating shaft 1 (driving rotating shaft), and a driven side V-pulley P ₂ is rotatably supported on this driven rotating shaft 24. This V pulley P ₂ is composed of a fixed pulley half 25 and a movable pulley half 26 , and a fixed pulley shaft 27 integrated with the fixed pulley half 25 is rotatable on the driven rotating shaft 24 via a ball bearing 28 . A movable pulley shaft 29, which is supported by the movable pulley half 26 and is integral with the movable pulley half 26, is fitted to be slidable in the axial direction on the fixed pulley shaft 27. A compression spring 31 is compressed between the back surface of the movable pulley half 26 and a support plate 30 fixed to the end of the stationary pulley shaft 27, and the elastic force of this compression spring 31 is applied to the movable pulley half 26. is biased toward the fixed pulley half 25.

The endless V-belt 10 is suspended between the conical surfaces of the fixed pulley half 25 and the movable pulley half 26, and when the driven V-pulley P ₂ is rotated by the operation of the endless V-belt 10, This rotational force is transmitted to the driven rotating shaft 24 via a centrifugal clutch C provided between the V-pulley _P2 and the driven rotating shaft 24.

In this embodiment, when the rotating shaft 1 is rotated,
The rotational power is generated by the drive side V pulley P ₁ and the endless V
It is transmitted to the driven side V-pulley _P2 via the belt 10. When the rotational speed of the rotating shaft 1 increases, the plurality of weight rollers 18 move radially outward due to the increase in centrifugal force, and the sliding portion 1 of the movable pulley half 3
4 is pushed by the weight roller 18 and moves to the left in FIG.
8 moves radially inward, and the sliding portion 14
Move to the right in the diagram. In this way, when the rotational speed of the rotating shaft 1 changes, the drive of the endless V-belt 10 and the contact position with respect to the driven side V-pulleys P ₁ and P ₂ change, and the gear ratio of the continuously variable transmission is automatically changed. The rotational power of the rotating shaft 1 is transmitted to the driven rotating shaft 24.

If the torque of the rotating shaft 1 suddenly fluctuates during rotational power transmission from the rotating shaft 1 to the driven rotating shaft 24, the endless V-belt 10 may slip or flap within the V-shaped groove 9, as described above. In addition, a large impact load acts on various parts such as the slide piece 19 and the like. However, in this embodiment, since the damper rubber 13 and the damper rubber 21 are interposed in the fixed pulley half 2 and the movable pulley half 3, respectively, the rotation shaft 1 is Rapid fluctuations in the torque transmitted from the V-pulley _P1 to the V-pulley P1 are alleviated, and therefore the occurrence of belt slips, flapping, and impact loads as described above can be avoided.

In the above embodiment, the present invention was applied to the driving pulley _P1 , but it is also possible to apply the present invention to the driven pulley _P2 .

FIG. 2 shows another embodiment of the invention. In this embodiment, in the movable pulley half 3, a conical surface portion is separated from the sliding portion 14 to form a face portion 32 similar to the face portion 12 in FIG. A damper rubber 33 is interposed between them. In this embodiment, the lamp plate 15 is directly fixed to the rotating shaft 1, and the sliding portion 14 and the lamp plate 15 constitute a supporting portion.

FIG. 3 is a cross-sectional view showing still another embodiment of the present invention, and with respect to FIG. 1, it is a cross-sectional view of a portion corresponding to the - line in the same figure. In this embodiment, the slide piece 19 is separate from the lamp plate 15, and a damper rubber 34 is interposed between the slide piece 19 and the lamp plate 15.
In this embodiment, the sliding portion 14, the guide piece 20
The slide piece 19 is the face part, and the ramp plate 15 is the support part.

Effects of the Invention As described above, the present invention fixes the fixed pulley half to the rotating shaft and engages the movable pulley half so as to be slidable in the axial direction. The variable diameter type V is capable of changing the contact position of the endless V belt with respect to the conical surface by adjusting the forward and backward movement of the movable pulley half with respect to the fixed pulley half by holding the endless V belt between the wheels.
In the pulley, both the fixed and movable pulley halves are constructed by integrating the face portion forming the conical surface and the support portion supported by the rotation shaft via an elastic buffer member, so that the rotation shaft Even if the torque transmitted from the to the face portion fluctuates, the torque fluctuation is alleviated by the elastic buffer member. Therefore, the slippage and flapping of the belt are reduced, and the durability of the belt is improved. In addition, the impact force caused by torque fluctuations is also reduced, and the strength required for each part is reduced, making it possible to reduce weight and cost, and also reduce noise during operation.

[Brief explanation of drawings]

FIG. 1 is a longitudinal sectional view showing one embodiment of the present invention, FIG. 2 is a sectional view showing a movable pulley half in another embodiment, and FIG. It is a sectional view of a corresponding part. 1... Rotating shaft, 2... Fixed pulley half, 3...
Movable pulley half, 4...Small diameter part, 5...Boss, 6
...Conical surface, 7... Nut, 8... Conical surface, 9...
... V-shaped groove, 10 ... Endless V belt, 11 ... Supporting part, 12 ... Face part, 13 ... Damper rubber (elastic buffer member), 14 ... Sliding part, 1
5... Lamp plate, 16... Inclined support surface, 1
7... Inclined support surface, 18... Weight roller, 1
9... Slide piece, 20... Guide piece, 21...
...damper rubber (elastic buffering member), 22 ... lamp plate boss, 23 ... step, 24 ... driven rotation shaft, 25 ... fixed pulley half, 26 ... movable pulley half, 27 ... fixed side Pulley shaft, 28...
Ball bearing, 29... Movable pulley shaft, 30...
Support plate, 31... Compression spring, 32... Face portion, 33... Damper rubber (elastic buffer member),
34... Damper rubber (elastic buffer member).

Claims (1)

[Scope of Claim for Utility Model Registration] (1) A fixed pulley half is fixed to a rotating shaft, and a movable pulley half is fitted so as to be slidable in the axial direction,
The endless V-belt is sandwiched between the opposing conical surfaces of both pulley halves, and the movable pulley half is adjusted to move forward and backward relative to the fixed pulley half, thereby changing the contact position of the endless V-belt with the conical surface. In the variable diameter V pulley, the fixed and movable pulley halves are integrated with a face portion forming the conical surface and a support portion supported by the rotating shaft via an elastic buffer member. A variable-diameter V-pulley characterized by having two configurations. (2) The face portion of the movable pulley half has a ramp plate that rotates integrally therewith, and the elastic buffer member is interposed between the ramp plate and the support portion supported by the rotating shaft. The variable diameter V-pulley according to item 1.